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TON DUC THANG UNIVERSITY FACULTY OF ELECTRICAL & ELECTRONICS ENGINEERING SOCIALIST REPUBLIC OF VIETNAM Independence – Freedom – Happiness Ho Chi Minh City, ……………………………… COURSE SYLLABUS INDUSTRIAL COMMUNICATION NETWORKS Course code: 403044 Information No of credits Time allocation Theory (hours) Pre-requisite Prior-completion N/A Programmable Logic Controller Pre-requisite code: Prior-completion code: N/A 403040 Co-requisite Programme N/A Bachelor in Electrical Engineering Bachelor in Automation and Control Engineering Co-requisite code: Programme Code: N/A 7520201 7520216 2(2,0) 30 Practice (hours) Self-study (hours) 60 Course objectives (COs) No Course Outcomes (COs) Expected Learning Outcomes (ELOs) Know the principles of digital communication equipment, the protocols and layers of communication networks ELO Understand the characteristics and applicable scopes of popular industrial networks, such as AS-i, ProfiBus/ProfiNet, Ethernet, CAN, Modbus, etc ELO 4, ELO Apply a communication network in industrial automation solutions in practice ELO 6, ELO 7, ELO 11, ELO 12 Course learning outcomes (CLOs) No Results COs ELOs Understand the definitions, terms and basic concepts in digital signal transmission and communication networks CO ELO Understand the operating characteristics of popular networks, such as AS-i, PROFIBUS/PROFINET, Ethernet, CAN, DeviceNet, etc CO ELO Apply a communication network for industrial control applications CO ELO Apply the communication skills and teamwork to implement projects; the writing and presenting skills to the academic research, CO ELO 11 Apply the time and resource management skills to implement the project CO ELO 12 Analyze the performance of industrial communication networks in specific applications CO 2, CO ELO Evaluate the advantages/disadvantages and applicable of specific communication networks in practice CO 2, CO ELO Brief course content This course introduces the history and trend of industrial communication networks; describes the basic terminology, protocols in digital communication techniques It also introduces the characteristics and operational principles of several common industrial communication networks, including: AS-i, Ethernet, PROFIBUS/PROFINET, CAN, DeviceNet, InterBus, ModBus, etc It also mentions a variety of typical applications in process/factory automation; building automation; SCADA in power systems to demonstrate how an industrial communication network can be applied in practice Student’s tasks - Attend: Attend at least 80% of classes Being late 02 times is equivalent to 01 absence Students who fail to attend at least 80% of classes will be prohibited from taking the final exam - Complete: Read the textbook and references as required; read more references to acquire more knowledge Submit the homework and assignments before due time - Participate: Pay attention to the lectures, participate actively and cooperatively in class activities organized by the instructor Willing to give comments or discuss on the topics that instructor introduces in class Take all quizzes, tests in class as well as mid-term exam and final exam Teaching materials - Textbooks: [1] Sunit Kumar Sen, [2014], FieldBus and Networking in Process Automation, CRC Press, New York - Supplementary readings: [2] Richard Zurawski, [2005], The Industrial Communication Technology Handbook, CRC Press, New York [3] Hoàng Minh Sơn, [2006], Mạng Truyền Thông Công Nghiệp, NXB Khoa học Kỹ thuật, Hà Nội - Additional readings: [4] Frithjof Klasen, Volker Oestreich, Michael Volz, [2011], Industrial Communication with Fieldbus and Ethernet, VDE Verlag MBH, Berlin-Offenbach [5] Đinh Hoàng Bách, Đồng Sĩ Thiên Châu, [2004], Nghiên cứu Triển khai Công Nghệ PLC Mạng Truyền Thông Công Nghiệp Điều Khiển Công Nghiệp, ĐH Tôn Đức Thắng, TP HCM Description of evaluation Evaluation category Weight (%) Types of questions In-class test 20% Process exercise Mid-semester Examination 30% Presentation Final Examination 50% CLOs [1], [2], [3] [3], [4], [5], [6], [7] - Multiple-choice questions - Constructed response test [1], [2], [3], [4], [5], [6] Schedule Session Contents Chapter 1: General introduction 1.1 History and trend 1.2 Roles and benefits of industrial comm networks 1.3 Classification 1.4 Typical applications Organization of teaching T E P D SelfCLOs study 6 [1], [7] 18 [1] Student's task [1], [7] Teaching methods: - Explicit teaching - Discussion Chapter 2: Basic concepts of digital transmission 2.1 Definitions 2.1.1 Information, Data, and Signal 2.1.2 Type of data and data acquisition in engineering systems 2.1.3 Data transmission and signals 2.2 Transmission modes 2.2.1 Parallel/serial bit transmission 2.2.2 Synchronous /asynchronous transmission 2.2.3 Simplex/Duplex 2.2.4 Baseband, Broadband, and multiplexing techniques Requirements [1] Preparation: - Read [3]: p - At class: - Actively participate in class activities - In class discussion - Solve the assigned homework After class: - Read [3]: p - - Reference: [2]: p 7.1 - 7.30 [4]: - 21 Preparation: - Read [1]: p.1-68 At class: - Actively participate in class activities - In class discussion - Solve the assigned homework After class: - Read [1]: p.1-68 - Reference: [2]: p 1.1 - 1.28 [3]: p 11 – 100 [4]: p.1 - 2.3 Protocol 2.3.1 Communication services 2.3.2 Protocol concepts 2.3.3 OSI Model 2.3.4 TCP/IP Teaching methods: - Explicit teaching - Discussion 2.4 Access control techniques 2.4.1 Master/Slave 2.4.2 TDMA 2.4.3 Token Passing 2.4.4 CSMA/CD 2.4.5 CSMA/CA 2.5 Error control techniques 2.5.1 Definition and classification 2.5.2 Parity check 2.5.3 CRC 2.5.4 Bit stuffing 2.6 Modulation techniques 2.6.1 Definition 2.6.2 NRZ, RZ 2.6.3 Manchester, AFP 2.6.4 FSK 2.7 Serial transmission standards 2.7.1 RS-232 2.7.2 RS-485 2.7.3 IEEE 802.3 (Ethernet) Teaching methods: - Explicit teaching - Discussion [1] Preparation: - Read [1]: p.1-68 At class: - Actively participate in class activities - In class discussion - Solve the assigned homework After class: - Read [1]: p.1-68 - Reference: [2]: p 1.1 - 1.28 [3]: p 11 – 100 [4]: p.1 - 2.8 Transmission media 2.8.1 UTP/STP 2.8.2 Coaxial 2.8.3 Optic cable 2.8.4 Power line communication 2.8.5 Wireless 2.9 Topology 2.9.1 Bus 2.9.2 Ring 2.9.3 Star 2.9.4 Tree 2.10 Network interconnection 2.10.1 Repeater 2.10.2 Bridge 2.10.3 Router 2.10.4 Gateway 2.11 Network software 2.11.1 Protocols used by vendors 2.11.2 Object-orientated programming Teaching methods: - Explicit teaching - Discussion Chapter 3: AS-i 3.1 Introduction 3.2 Physical features of AS-i 3.3 Data specification of AS-i 3.4 AS-i components 3.5 Example projects Teaching methods: - Explicit teaching - Discussion Preparation: - Read [1]: p.1-68 At class: - Actively participate in class activities - In class discussion - Solve the assigned homework After class: - Read [1]: p.1-68 - Reference: [2]: p 1.1 - 1.28 [3]: p 11 – 100 [4]: p.1 - [1] [2], [3], [6] Preparation: - Read [1]: p.213 - 219 At class: - Actively participate 403040: Full [2], [3], [6] in class activities content - In class discussion - Solve the assigned homework After class: - Problem solving Chapter 4: PROFIBUS 4.1 Introduction 4.2 Physical features of Profibus 4.3 Data specification of Profibus 4.4 Profibus profiles: FMS, DP, PA 4.5 Example projects - Read [1]: p.213 - 219 - Reference: [3]: p.203 – 211 [5]: p.1 - 36 6 3 12 Teaching methods: - Explicit teaching - Discussion - Problem solving Chapter 5: PROFINET 5.1 Introduction to Industrial Ethernet 5.2 PROFIBUS vs PROFINET 5.3 IRT in PROFINET I/O 5.4 PROFINET applications Teaching methods: - Explicit teaching - Discussion - Problem solving [2], [3], [6] Preparation: - Read [1]:p.147 - 184 At class: - Actively participate in class activities - In class discussion 403040: Full - Solve the assigned [2], [3], [6] content homework After class: - Read [1]: p.147 - 184 - Reference: [2]: p.10.1 -10.23 [5]: p.36 - 77 [2], [3] [6] Preparation: - Read [2]:p.11.111.26 At class: - Actively participate 403040: Full in class activities [2], [3], [6] content - In class discussion - Solve the assigned homework After class: - Read [2]: p.11.111.26 - Reference: [4]: p.115 -134 5.5 Design guideline of network projects 5.5.1 Example of AS-i application using CP 243-2 5.5.2 Example of ProfiBus application 5.5.3 Example of PROFINET application using S7-1500 3 Preparation: - Read [2]:p.11.111.26 At class: - Actively participate in class activities - In class discussion 403040: Full [2], [3], [6] - Solve the assigned content homework After class: - Read [2]: p.11.111.26 - Reference: [4]: p.115 -134 Teaching methods: - Explicit teaching - Discussion - Problem solving Chapter 6: Industrial Networks 6.1 CAN 6.2 DEVICENET 6.3 MODBUS 6.4 Exercises Teaching methods: - Explicit teaching - Discussion - Problem solving [2], [3], [4], [5], [6] [2], [3], [4], [5], [6] Preparation: - Read [1]: p.185- 212 At class: - Actively participate in class activities - In class discussion - Solve the assigned homework After class: - Read [1]: p.185- 212 - Reference: [4]: p.29 - 40; p.72 - 81; p.183 – 197 Chapter 7: Industrial Network Applications 7.1 Automotive applications 7.2 Building Automation applications 7.3 Process Control applications 7.4 Power System applications 10 Teaching methods: - Explicit teaching - Discussion - Problem solving Total 6 21 60 [4], [5], [6] , [7] [4], [5], [6] , [7] Preparation: - Read [2]: Chapter 29, 30, 33, 34, 36, 37, 39, 41 At class: Presentation ... transmission and communication networks CO ELO Understand the operating characteristics of popular networks, such as AS-i, PROFIBUS/PROFINET, Ethernet, CAN, DeviceNet, etc CO ELO Apply a communication. .. Analyze the performance of industrial communication networks in specific applications CO 2, CO ELO Evaluate the advantages/disadvantages and applicable of specific communication networks in practice... This course introduces the history and trend of industrial communication networks; describes the basic terminology, protocols in digital communication techniques It also introduces the characteristics